Damage tolerance of bio-inspired helicoidal composites under low velocity impact

Ginzburg, Dmitri; Pinto, Fulvio; Iervolino, Onorio; Meo, Michele

doi:10.1016/j.compstruct.2016.10.097

Cited by 131 publications

(69 citation statements)

References 25 publications

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“…This optimal range, which features relatively small pitch angles, is remarkably similar to the pitch angles adopted by natural Bouligand structures. 4,29 Previously, experiments with bio-inspired, ber-reinforced composites that contain Bouligand structures have shown that their damage tolerance during impact increases with decreasing g. 14,15 However, this is the rst time that an optimal pitch angle range has been described for the Bouligand structures that maximizes their ballistic performance, which offers guidance for how 1D nanostructures should be arranged layer-by-layer to produce damage tolerant lms.…”

Section: Effect Of Lm Structure On Ballistic Performancementioning

confidence: 99%

“…13,14 Potential applications of these materials include protective shields for vehicles, body armor, eyewear, packaging, and stretchable and wearable electronics. [14][15][16] While numerous experimental and computational investigations have attempted to explain the structure-property relationships of Bouligand microstructures that give rise to its impact tolerance, no consensus has emerged regarding the dominant deformation mechanisms associated with this microstructure. Bouligand lamellae in sh scales have been shown to reorient towards external tensile loads during mechanical testing using X-ray scattering, leading to enhanced toughness through stretching and sliding mechanisms.…”

Section: Introductionmentioning

confidence: 99%

“…[18][19][20][21][22][23][24] Experiments and nite element analyses of Bouligand structured composites have demonstrated improved impact resistance and higher residual strength (as much as 80%) compared to quasi-isotropic structures by effectively spreading impact energy in-plane. 14,15,20 Ballistic impact tests have revealed that Bouligand structures ( Fig. 1b) with smaller interply, or pitch (g), angles (22.5 # g # 45 ) lead to higher ballistic limits and can absorb up to 15% more energy during ballistic impacts with larger delamination areas and lower degrees of internal damage.…”

Section: Introductionmentioning

confidence: 99%

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Impact resistance of nanocellulose films with bioinspired Bouligand microstructures

et al. 2019

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The Bouligand structure features a helicoidal (twisted plywood) layup of fibers that are uniaxially arranged in-plane and is a hallmark of biomaterials that exhibit outstanding impact resistance. Despite its performance advantage, the underlying mechanisms for its outstanding impact resistance remain poorly understood, posing challenges for optimizing the design and development of bio-inspired materials with Bouligand microstructures. Interestingly, many bio-sourced nanomaterials, such as cellulose nanocrystals (CNCs), readily self-assemble into helicoidal thin films with inter-layer (pitch) angles tunable via solvent processing. Taking CNC films as a model Bouligand system, we present atomisticallyinformed coarse-grained molecular dynamics simulations to measure the ballistic performance of thin films with helicoidally assembled nanocrystals by subjecting them to loading similar to laser-induced projectile impact tests. The effect of pitch angle on the impact performance of CNC films was quantified in the context of their specific ballistic limit velocity and energy absorption. Bouligand structures with low pitch angles (18-42 ) were found to display the highest ballistic resistance, significantly outperforming other pitch angle and quasi-isotropic baseline structures. Improved energy dissipation through greater interfacial sliding, larger in-plane crack openings, and through-thickness twisting cracks resulted in improved impact performance of optimal pitch angle Bouligand CNC films. Intriguingly, decreasing interfacial interactions enhanced the impact performance by readily admitting dissipative inter-fibril and inter-layer sliding events without severe fibril fragmentation. This work helps reveal structural and chemical factors that govern the optimal mechanical design of Bouligand microstructures made from high aspect ratio nanocrystals, paving the way for sustainable, impact resistant, and multifunctional films.

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Section: Effect Of Lm Structure On Ballistic Performancementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Impact resistance of nanocellulose films with bioinspired Bouligand microstructures

et al. 2019

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“…The biomimetic models were found to have improved fracture toughness over conventional laminate specimen. Ginzburg et al [20] conducted numerical studies of helicoidal composites subject to Low Velocity Impact (LVI), and found that helicoidal composites had the least amount of fiber damage, post-impact.…”

Section: Biomimetic Structures Of Dactyl Limbsmentioning

confidence: 99%

“…Some of these models were subsequently modified to incorporate related features, from other, suitable geometries such as Bouligand structures [14,20,[31][32][33][34] and biological sutures [25]. Bouligand structures were mimicked by orienting each layer of nacre mimetic aluminum plates at a slightly different angle in the plane of the lamina, while sutures were created as jigsaw interlocks between adjacent tablets in the same plane (L3, L4).…”

Section: Laminate Geometries (L1-l5)mentioning

confidence: 99%

Bioinspired designs for shock absorption, based upon nacre and Bouligand structures

Raphel¹,

Jacob²,

Viswanathan³

2019

SN Appl. Sci.

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Biological materials such as nacre, found in mollusk shells and Bouligand structures, found in the armor of many arthropods, exhibit values of toughness that are much higher than their constituent materials. This is achieved via specific arrangements and combinations of natural materials. In all biomimetic studies seen in literature so far, any one type of material alone is chosen for mimicry. The present work aims to create a set of biomimetic designs that incorporate macroscopic features of both nacre and Bouligand structures, so as to achieve toughness amplification in the given material. Finite element analysis (FEA) of relevant geometric designs are initially performed using ABAQUS software and experimental validation of the most promising model (which was found to show a 46.15% improvement over the reference model) is done. The testing method selected for both simulations as well as experiment is the Charpy impact test (ASTM E23).

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Bioinspired Golden Spiral Shapes on Crushing Protection Behaviors of Tubular Structures

Sherman,

Zhang,

Waheed

et al. 2023

Adv Eng Mater

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Advanced structure design for energy absorption is a long‐lasting pursuit due to its fascinating scientific merit in mechanics and important engineering application. Curves, a type of mathematical variation in geometry, are widely adopted in the biological system and biomaterial structures after long‐time nature evolution toward optimization and adaption. Inspired by nature, a novel type of tubular structure is designed with golden spiral curvature. With the variations in the hierarchy of the supporting spirals and the number of arms, a maximum of 38.8% increase is demonstrated in performance over an uncurved counterpart structure. The computational modeling reveals that the additional added golden spiral arms within the tube enhance the rigidity and increase the energy dissipation via progress buckling involved by additional materials such that the energy absorption upon crushing is significantly improved. Theoretical models then provide intrinsic underlying mechanics analysis with more intuitive design guidance for such structures. Results develop an efficient yet simple design based on widely accepted tubular structure design for impact protection, enrich the mechanistic understanding of the nonlinear buckling behaviors, and provide applicable design guidance for engineering structures.

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Damage tolerance of bio-inspired helicoidal composites under low velocity impact

Cited by 131 publications

References 25 publications

Impact resistance of nanocellulose films with bioinspired Bouligand microstructures

Impact resistance of nanocellulose films with bioinspired Bouligand microstructures

Bioinspired designs for shock absorption, based upon nacre and Bouligand structures

Bioinspired Golden Spiral Shapes on Crushing Protection Behaviors of Tubular Structures

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